47份水稻品种资源的ISSR遗传多样性分析

为研究广东省惠州市种植的常规水稻品种的遗传多样性,本实验利用ISSR标记对47份水稻品种资源进行遗传多样性检测。从49条引物中筛选出5条重复性好,条带清晰的引物进行PCR扩增,共扩增出53条带,每个引物可以扩增出9～13条带,平均为10．6条,其中47条具有多态性,比率为88．7％。不同水稻品种间遗传相似系数变幅为0．319～0．936,平均达0．691,说明ISSR标记能够揭示材料间较高的遗传多样性。通过聚类,从分子水平对水稻品种资源的遗传关系进行分析,并对47份水稻品种资源进行分类,ISSR标记能将47份水稻品种完全区分开,为水稻品种资源的研究利用提供参考。     

RAPD和ISSR标记对甜瓜种质遗传多样性的研究

利用RAPD和ISSR两种分子标记技术对37份甜瓜(CucumismeloL.)种质进行了遗传多样性研究.在供试材料中筛选到具有多态性的RAPD引物21个,ISSR引物10个(其中ISSR-2与ISSR-4等量混合组成ISSR-10引物对).RAPD引物共扩增出多态性带106条,多态性条带比率(PPB)为58.62%,平均多态信息量(PIC)为0.47;ISSR引物共扩增出多态性带73条,PPB值为65.51%,平均PIC值为0.53.根据两种标记的结果,采用UPGMA聚类分析,将供试材料分为两大类群野生甜瓜和栽培甜瓜;栽培甜瓜又分为厚皮甜瓜和薄皮甜瓜两大亚群,各野生甜瓜种质之间的遗传距离较大,这与其分类地位基本一致.两种分子标记的分析结果呈极显著正相关(r=0.62>r=0.01).研究表明,RAPD和ISSR标记可用于甜瓜种质遗传多样性的研究.     

利用ISSR揭示不同类型月季遗传多样性

本研究应用正交设计法对ISSR反应体系中的各个主要影响因子进行了优化筛选,确立了适合月季ISSR-PCR反应的最佳体系。结果表明,25μL的ISSR反应体系中各组分的最适浓度分别为：1×PCR缓冲液、1U Taq DNA聚合酶、800pmol／L 引物、0.16mmol／L dNTPs、Mg^2＋ 1.5mmol／L。筛选了33个ISSR引物,共得到了11个多态性比较高的ISSR引物,占所筛引物的33.33％。利用筛选出的11条ISSR引物对3种月季类型的23份月季材料进行遗传多样性分析,共扩增出477条DNA带,其中多态性位点有14个,平均每条引物可以检测到4.5个多态性位点。用NTSYS软件对样品进行了UPGMA聚类分析,聚类结果表明丰花月季基本能聚为一类,切花月季与藤本月季交叉聚在一起。这表明月季种质的遗传差异与其应用分类的相关性不紧密。     

利用SSR标记分析部分粳稻品种的遗传多样性

以我国16个粳稻品种为材料,包括水稻雄性不育系、恢复系、杂交种以及少量常规稻,从分布在水稻基因组的12条染色体上300对SSR引物中筛选出14对多态性丰富、重复性高的引物,这些引物在16份材料间共扩增出61个多态性片段,平均每对SSR引物可检测到4.36个等位基因。聚类分析表明:品种间遗传相似系数在0.57~0.97之间。生产中应用的BT型水稻雄性不育系与恢复系分别聚类于不同的类群,遗传关系较远。     

37份龙眼种质资源亲缘关系的ISSR分析

本研究利用ISSR技术对37份龙眼种质资源进行遗传多样性检测。研究结果表明,从100条ISSR引物中筛选出7条重复性好,条带清晰的引物对37份龙眼品种基因组DNA进行扩增,共扩增出54条带,其中43条具有多态性,比率为79．6％。不同龙眼品种间遗传相似系数变幅为0．69～0．97,平均达0．83,说明ISSR标记能够揭示材料间较高的遗传多样性。UPGMA聚类结果表明,ISSR标记能将37份龙眼品种完全区分开,并能将来源于中国、越南和泰国的37份龙眼品种分别聚类到中国、越南和泰国三大品种群,说明龙眼品种资源的亲缘关系与地理因素有关,三个国家的龙眼品种之间存在较大的遗传差异。本研究结果将为为龙眼品种资源的研究利用提供参考。     

丹参遗传多样性的SRAP标记分析

相关序列扩增多态性(SRAP)是一种新发展起来的分子标记。试验通过建立优化的丹参SRAP反应体系,从88对引物组合中筛选得到36对多态性引物组合,对生长在四川中江、陕西商洛、山东临沂、安徽亳州和安徽凤阳5个丹参主产区的6个丹参种群进行了遗传多样性分析。结果表明:36对多态性引物组合共产生782条多态性条带,平均每个引物组合产生21.7条多态性条带,显示了较高的多态性。应用NTSYS软件聚类分析36对引物组合的扩增结果,供试材料分为两大类,Jaccard’s遗传相似系数在0.6774~0.8225之间,说明SRAP技术可有效地应用于丹参的遗传多样性及亲缘关系的研究。     

SSR和SRAP标记研究油菜杂交种骨干亲本的遗传多样性

用SSR和SRAP两种分子标记方法研究51份甘蓝型油菜杂交种亲本系的遗传多样性,并对两种分子标记研究结果进行比较。结果发现,在51份材料中,45对SSR引物共扩增出194条多态性条带,平均每对引物为4.3条,25对SRAP引物共扩增出197条多态性条带,平均每对引物为7.9条。UPGMA聚类分析表明,SSR和SRAP标记都可将51份亲本材料划分为五大类群,本所选育的玻里马细胞质雄性不育系（Polima CMS）的主要保持系和恢复系都聚在同一类群的不同亚群中。根据系谱资料分析发现,SRAP标记划分的类群与系谱资料更为接近,SRAP标记更适用于遗传关系较近材料的遗传多样性分析。SRAP标记揭示的亲本间遗传距离要大于SSR标记揭示的遗传距离。两种不同标记方法揭示出油菜亲本遗传多样性的差异主要是由不同的标记方法揭示的标记位点等位基因变异数不同造成的。     

利用RAPD与SSR技术进行野生大豆种群内分化的研究

利用RAPD和SSR技术对25°N野生大豆种群16个样本进行分子标记,从150多个RAPD引物中筛选出具有多态性的引物20个,共扩增出146个标记位点,其中具有多态性的有60个,占总位点的40.8%,平均遗传距离为0.1536,杂合度为0.3248.从60对SSR引物中筛选出14对具有多态性的引物,平均遗传距离为0.2209,杂合度为0.6961.聚类分析可将25°N野生大豆16个样本分成5类,表明种群内存在大量的遗传变异.为研究野生大豆种群内及种群间的遗传多态性探索了有效方法,并提出野生大豆核心种质资源的保存及取样对策.     

甜菜品种（系）的ISSR标记数字指纹图谱构建及聚类分析

摘要：本文针对来源于荷兰的4个引进甜菜品种和国内的6个甜菜品系（其中2个为一年生野生甜菜）进行了ISSR指纹图谱构建和聚类分析研究。筛选出稳定性高且多态性好的6个引物用于试验。利用筛选的6条引物ISSR-PCR 共扩增出51个条带, 其中多态性条带百分率为86.3%. 利用该6条引物ISSR-PCR建立的指纹图谱能将试验中的全部甜菜品种都鉴定区分开。只利用2条引物L1和UBC846 扩增的8个多态性条带构建了10个甜菜品种（系）的数字指纹识别码,该数字指纹图谱能完全区分10个甜菜品种（系）,结果显示ISSR 指纹图谱能非常有效的鉴定不同的甜菜品种。利用生物软件NTSYS-pc针对10个试验甜菜品种（系）的ISSR 扩增条带进行遗传相似性聚类分析,结果显示10个甜菜品种（系）的相似系数为0.43与0.83之间,平均为0.62。利用非加权组平均法（UPGMA）进行聚类分析,结果显示10个甜菜品种（系）聚类为2个组和3个亚组。UPGMA 聚类分析能清楚的显示10个甜菜群体间的遗传关系并且聚类结果与10个甜菜群体的特性一致, 说明ISSR标记能用于甜菜不同群体间遗传距离的评估。     

青钱柳种质资源多样性SRAP初步分析

为了利用分子标记方法评价青钱柳种质资源的遗传多样性,本文对青钱柳DNA的提取、SRAP扩增体系重要参数进行了优化,运用优化体系筛选多态性引物,并用1对引物对青钱柳9个种源进行了遗传多样性初步分析。研究结果建立了适于青钱柳SRAP的扩增体系;从110对SRAP引物中筛选出了13对多态性引物,运用1对引物组合Me7＋Em2扩增获得21个多态性位点,多态率达100%。遗传多样性分析表明有效等位基因数（Ne）为1.3429,平均Shannon＇s信息指数（I）为0.3687,Nei＇s基因多样性指数（H）为0.2267,种源的遗传分化指数Gst为0.1983;聚类分析结果表明9个种源在遗传距离0.100处聚为3类,聚类结果和地理距离之间呈现较高的相关性。本文的研究结果表明所建立的青钱柳种质资源库具有广泛的遗传多样性,为进一步的开发利用提供了条件。     

Analysis of genetic diversity of Ruthenia Medic (Medicago ruthenica (L.) Trautv.) in Inner Mongolia using ISSR and SSR markers

Ruthenia Medic is tolerant to drought, cold, high salinity, resistance to trampling and high quality features. Inter-simple sequence repeat (ISSR) and simple sequence repeat (SSR) molecular markers were employed for the first time to access the genetic diversity and relationships of 30 wild Ruthenia Medic accessions obtained from Inner Mongolia in the present study. A total of 94 bands were amplified by ten ISSR primers, of which 83 (88.5 %) were polymorphic, and 57 polymorphic bands (80.4 %) were observed in 69 bands amplified by ten SSR primers. Shannon’s information index (I = 0.487), and average expected heterozygosis (He = 0.329) generated by ISSR primer were higher than that of SSR analysis (I = 0.372, He = 0.231). The study indicated that ISSR were more effective than SSR markers for assessing the degree of genetic variation of Ruthenia Medic. UPGMA cluster analysis revealed inconsistencies in the clustering patterns, as the Mantel’s test between the dendrograms for ISSR and SSR data indicated a poor fit for the ISSR and SSR data types (r = 0.0970). Whereas the pattern of clustering of the genotypes remained relatively the same in ISSR and combined data of ISSR and SSR. The results of principal components analysis also supports their UPGMA clustering. These results have an important implication for Ruthenia Medic germplasm characterization, improvement, and conservation.     

Assessment of genetic diversity in Galega officinalis L. using ISSR and SRAP markers

Goat’s rue is well known for its traditional medicinal importance. In the present study, inter-simple sequence repeat (ISSR) and sequence related amplified polymorphism (SRAP) molecular markers were employed for the first time to access the genetic diversity and relationships of 35 wild goat’s rue accessions obtained from Russia and part of Europe countries. A total of 100 bands were amplified by ten ISSR primers, of which 77(77%) were polymorphic, and 59 polymorphic bands (67.1%) were observed in 88 bands amplified by seven SRAP primers. Polymorphic information content (PIC?=?0.426), Shannon’s information index (I?=?0.432), and average expected heterozygosity (He?=?0.292) generated by ISSR primer were higher than that of SRAP analysis (PIC?=?0.422, I?=?0.380, and He?=?0.257,). The study indicated that ISSR were more effective than SRAP markers for assessing the degree of genetic variation of goat’s rue. UPGMA cluster analysis revealed inconsistencies in the clustering patterns, as the Mantel’s test between the dendrograms for ISSR and SRAP data indicated a poor fit for the ISSR and SRAP data types (r?=?0.358). Whereas the pattern of clustering of the genotypes remained more or less the same in SRAP and combined data of ISSR and SRAP. The results of principal coordinates analysis also supports their UPGMA clustering. These results have an important implication for goat’s rue germplasm characterization, improvement, and conservation.     

Characterization of Some Italian Common Bean (<Emphasis Type="Italic">Phaseolus Vulgaris</Emphasis> L.) Landraces by RAPD,Semi-random and ISSR Molecular Markers

Randomly amplified polymorphic DNA (RAPD), inter-simple sequence repeat (ISSR) and a semi-random PCR system were used to analyze the genetic diversity of 16 Italian common bean landraces and their relationship to four commercial cultivars. Of the primers tested, 8 ISSR, 6 RAPD and 7 semi-random primers produced polymorphic and reproducible DNA fragments. A higher proportion of polymorphic bands were observed using ISSR (85%) and semi-random (90%) primers than RAPD (69%) method. The combination of any two semi-random markers allowed the identification of all 20 bean genotypes. In contrast ISSR (except for primer (CAC)₃GC) and RAPD markers appeared to be less informative as more than two markers were necessary to achieve the same diagnostic level. Moreover, 7 ISSR, 2 RAPD and 8 semi-random exclusive bands were identified as putative population-specific markers. Semi-random and ISSR derived dendrograms showed similar tendencies in terms of genetic relatedness, whereas clustering of genotypes within groups was not similar when compared with the RAPD technique. Despite the different ability to resolve genetic variation among the investigated landraces, two major clusters with less than 60% (ISSR) and 40% (RAPD and semi-random) genetic similarity were formed with all three marker systems. The two groups were correlated with the phaseolin patterns and seed size of the landraces. The analysis showed that the cultivar ȁ8Lingua di Fuocoȁ9 and most of the landraces (13 out of 16) collected in Italy belong to the Andean gene pool, whereas only the three populations from Pratomagno belong to the Middle American gene pool.     

RAPD and ISSR molecular markers in <Emphasis Type="Italic">Olea europaea</Emphasis> L.: Genetic variability and molecular cultivar identification

Thirty Portuguese and eight foreign olive (Olea europaea L.) cultivars were screened using Random Amplified Polymorphic DNA (RAPD) and Inter-Simple Sequence Repeat (ISSR) markers. Twenty RAPD primers amplified 301 reproducible bands of which 262 were polymorphic; and 17 ISSR primers amplified 204 bands of which 180 were polymorphic. The percentage of polymorphic bands detected by ISSR and RAPD was similar (88 and 87%, respectively). The genetic variability observed was similar in the Portuguese and foreign olive cultivars. Seven ISSR and 12 RAPD primers were able to distinguish individually all 38 olive cultivars. Twenty specific molecular markers are now available to be converted into Sequence Characterised Amplified Region (SCAR) markers. Relationships among Portuguese and foreign cultivars is discussed.     

菊属11个野生种和12个栽培品种遗传关系的ISSR分析

为进一步明确菊属野生种与栽培品种的遗传关系和多样性,本研究利用ISSR分子标记技术对菊属11个野生种和12个栽培品种之间的遗传关系进行比较分析。从75个ISSR引物中筛选出了14个引物,对供试材料的DNA进行扩增,共获得142条清晰可辨的谱带,多态位点比率为95.1%;菊属野生种的平均有效等位基因数（effective number of alleles,Ne）、平均Nei＇s基因多样性指数（Nei’s gene diversity,H）及Shannon信息指数（shannon’s information index,I）均高于栽培菊花,说明各野生种间基因差异比较显著,多态性强于栽培品种。UPGMA聚类结果表明：菊属野生种呈现由低倍向高倍进化的趋势;栽培菊花之间遗传关系复杂,大体可以推断出平瓣是菊花的基本瓣形;菊花脑与栽培菊花亲缘关系最近,小红菊、龙脑菊、若狭滨菊与栽培菊花关系亦较近,神农香菊与其它材料关系最远。本研究的结果表明菊属野生种与栽培品种之间遗传关系比较复杂,而ISSR分子标记技术可以较好地从分子水平上揭示出菊属植物间的遗传关系。     

RAPD and ISSR fingerprinting in cultivated chickpea (<Emphasis Type="Italic">Cicer arietinum</Emphasis> L.) and its wild progenitor <Emphasis Type="Italic">Cicer reticulatum</Emphasis> Ladizinsky

Detection of genetic relationships between 19 chickpea cultivars and five accessions of its wild progenitor Cicer reticulatum Ladizinsky were investigated by using RAPD and ISSR markers. On an average, six bands per primer were observed in RAPD analysis and 11 bands per primer in ISSR analysis. In RAPD, the wild accessions shared 77.8% polymorphic bands with chickpea cultivars, whereas they shared 79.6% polymorphic bands in ISSR analysis. In RAPD analysis 51.7% and 50.5% polymorphic bands were observed among wild accessions and chickpea cultivars, respectively. Similarly, 65.63% and 56.25% polymorphic bands were found in ISSR analysis. The dendrogram developed by pooling the data of RAPD and ISSR analysis revealed that the wild accessions and the ICCV lines showed similar pattern with the dendrogram of RAPD analysis. The ISSR analysis clearly indicated that even with six polymorphic primers, reliable estimation of genetic diversity could be obtained, while nearly 30 primers are required for RAPD. Moreover, RAPD can cause genotyping errors due to competition in the amplification of all RAPD fragments. The markers generated by ISSR and RAPD assays can provide practical information for the management of genetic resources. For the selection of good parental material in breeding programs the genetic data produced through ISSR can be used to correlate with the relationship measures based on pedigree data and morphological traits to minimize the individual inaccuracies in chickpea.     

Comparative Analysis of Genetic Diversity in Two Tunisian Collections of Fig Cultivars Based on Random Amplified Polymorphic DNA and Inter Simple Sequence Repeats Fingerprints

This study characterized the genetic diversity of 18 Tunisian fig cultivars using random amplified polymorphic DNA (RAPD) and inter simple sequence repeats (ISSR). Both random and ISSR primers tested generated a total of 116 RAPD and 47 ISSR markers. Considerable genetic variation was observed among fig cultivars sampled from two regional Tunisian collections with an average diversity of 4.57. RAPD and ISSR banding patterns and genetic distances values reflected the high level of diversity among the collections and lower variability between the two collections. The correlation between the RAPD and ISSR similarity matrices computed for the 153 pairwise comparisons among the 18 varieties was lower and significant. An analysis of molecular variance showed that 92% of the total genetic diversity resided within collections, whereas only 8% between collections. The results indicated that in the local fig germ plasm the information provided by RAPD and ISSR is not analogous, most likely as a consequence of the fact that the two classes of markers explore, at least in part, different portions of the genome.     

Genetic diversity and phylogenetic relationship of <Emphasis Type="Italic">Tadehagi</Emphasis> in southwest China evaluated by inter-simple sequence repeat (ISSR)

There are many valuable Tadehagi accessions in southwest China, but it is unknown that the genetic diversity and phylogenetic relationship of these Tadehagi resources. This report is the first study in which 41 primers of inter-simple sequence repeat (ISSR) were used to assess the genetic diversity of 36 Tadehagi accessions from 3 provinces in the southwest of China. Totally, 30 usable ISSR primers detected 163 polymorphic bands among the 36 accessions, which suggested high utility of ISSR primers in the genetic analysis of Tadehagi accessions. Genetic similarity coefficients among all of the accessions ranged from 0.54 to 0.92 with the average of 0.79 based on the ISSR data, indicating high level of genetic variation in Tadehagi resources from the southwest of China. As for the 3 population, Hainan population had the maximum average genetic similarity coefficients of 0.81, while similarity coefficient of Guangxi and Yunnan population was 0.75 and 0.74, respectively. All the 36 Tadehagi accessions were divided into 4 groups in the UPGMA dendrogram constructed from genetic similarity coefficients. The Tadehagi accessions from Yunnan and Guangxi provinces showed more genetic variation and occupied the bottom of the dendrogram. On the contrary, those from Hainan Province had less genetic variation and clustered in the middle and top of the dendrogram. The information on the genetic diversity and phylogenetic relationship from this study is propitious to construct a core germplasm collection and develop novel Tadehagi cultivars with desired economic traits.